BRPI0614584A2 - bleed channel for a metallurgical furnace - Google Patents

Abstract

BLEEDING CHANNEL FOR A METALLURGICAL OVEN The invention relates to a bleed channel (1) for a metallurgical furnace, consisting of at least one bleed brick (10, 11, 12) and a cooling device in the channel region bleed (1). The cooling device is executed like a glove (14) indirectly cooling at least one bleed brick (10, 11, 12) and enclosing it at least partially in the region of the oven wall (3).

Description

Bleeding Channel for a Metallurgical Oven

The invention relates to a bleed channel for a metallurgical furnace, especially for an electric reduction furnace, consisting of at least one bleed brick and a cooling device in the bleed channel region.

From the Japanese Patent Summary 05 - 33 15 21 a bleed channel is known, wherein the bleed channel consists of a shroud made of shroud tube provided with cooling channels. This surrounding tube is so inserted into a hole in the side wall of the oven with a positioning filler that the front wall of the surrounding tube determines the inner wall of the oven.

In the SMS - Demag publication "With SAF technology for success", you can find on page 12, left column: Bleeding holes construction mode - Bleeding holes can be offered in conventional construction mode. For use under higher loads, water cooled elements are available for metal bleed, CU brick and slag.

In addition, it is known that the sangria bleed bricks in the masonry cladding are washed and the wall structure is destroyed. This no longer guarantees the thermal conductivity and sealability of the bleed channel. Damaged or clogged bleed bricks should be serviced / replaced regularly as furnaces operate continuously. For repair / exchange, the oven must be switched off. This implies production interruptions. In order to keep these production interruptions as low as possible, the bleed channel or bricks are cleaned / replaced as much as possible when high temperatures are still present inside the oven. With this execution, the region around the bleed channel is not cooled. This execution is represented in figures 1 and 2.

In other known bleed channels, the bleed channels are directly cooled, whereby the cooling medium, preferably water, is introduced into the bleed channels into the furnace and carried forward to the furnace masonry lining region. In case of damage to the bleed channel, therefore, the cooling medium can penetrate the oven.

The invention aims to improve the known bleed channels, especially their strength and service life, and to avoid the aforementioned drawbacks. With improved execution of the bleed channel the necessary maintenance work should be further simplified and safety improved.

This objective is achieved, according to the invention, by the fact that in a second preamble bleed channel of claim 1, the cooling device is performed as a glove enclosing the bricks of the furnace wall region.

Other configurations of the bleed channel comprise from the respective subclaims.

The decisive advantage of the bleed channel according to the invention is that the bleed bricks are not then encircled by the glove the entire length. The bleed brick pointing into the oven (multi-part execution) or bleed brick segment (one-piece bleed brick) is not encased in the sleeve. This bleed brick ends flush with the furnace lining.

With the bleed channel according to the invention, the cooling medium is conducted from the outside into or onto the copper sleeve. The bleed channel is cooled indirectly due to the high thermal conductivity of the copper daluva. No cooling medium is led into the oven, as the cooling channels in the luvase are found just outside the oven shell.

The glove minimizes natural rinsing by slag / metal etc. hot and the bleed channel is kept in the pre-configured shape.

The position of the bleed hole is still defined. Oven masonry coating of the bleed hole remains intact. Worn / clogged bleed bricks can be easily removed.

The cooling device according to the invention, the glove, enables easy / simple assembly of the new bleed bricks, and low cost standardized brick formats can be employed.

Due to the glove there is intensive cooling down to the interior of the oven, which allows the melt to consolidate faster and allows faster and safer access to the bleed hole. Improvements indicated avoid or reduce furnace downtimes.

An exemplary embodiment of the invention and the current state of the art will be explained in detail with the aid of rather schematic drawings. Show:

Fig. 1 - in cross-sectional side view a known running channel bleed,

Fig. 2 - in view of the sectional top the channel bleed from fig. 1,

Fig. 3 - in cross-sectional side view, a channel bleed according to the invention and

Fig. 4 - In view of the cross-sectional top, the tapered channel of fig. 3

1 shows a bleed channel 1 in a known embodiment which is arranged in a bleed hole 2 of a furnace consisting of furnace wall 3 and masonry coating 4.

In Figure 2 it can be seen from the top view the bleed channel 1 of Figure 1. In the shown embodiment, the bleed channel 1 consists of several bleed bricks 5, 6, 7, 8. The bleed brick 1 points to the interior of the bleed 1. The oven and the bleed bricks 7, 8 are outside the oven wall 3 and are surrounded by a plate construction 9 for stabilization.

Figure 3 shows the bleed channel 1 according to the invention in sectional side view. In a bleed hole 2 are arranged three bleed bricks 10, 11, 12, with the bleed brick 10 pointing towards the interior of the furnace terminating with the furnace lining 4 of the furnace. The outer bleed brick 12, pointing away from the furnace, projects beyond the furnace wall 3. To this end, a wall 13 is fixed to the furnace wall to support the bleed brick12. In the furnace wall region 3 the bleed bricks 11, 12 are enclosed by a glove-shaped cooling device 14. The glove 14 terminates with the front area of the bleed brick 12 on the outside of the furnace. Door 14 protrudes partially into the oven masonry cover 4. As shown, the direct region on the inner wall of the furnace is not included by glove 14. For example, the last bleed brick 10 pointing to the interior of the furnace is not enclosed by the glove.

In figure 4, the bleed channel 1 is shown in top view in section. The sleeve 14, which consists of solid copper, is provided in its projecting region out of a cooling channel 15, which is made in the form of a ring in the embodiment shown. The side walls of the glove 14 have connections 16, 17 for cooling water adduction and cooling water discharge.

REFERENCE LIST

1 bleed channel 2 bleed hole 3 kiln wall 4 masonry cladding 5 bleed brick 6 bleed brick 7 bleed brick 8 bleed brick 9 plate construction 10 bleed brick 11 bleed brick 12 bleed brick 13 rebound 14 sleeve15 cooling channel

16 connections

17 connections

Claims (8)

1. Bleeding channel (1) for a metallurgical furnace, consisting of at least one bleed brick (10, 11, 12) and a cooling device in the region of the bleeding channel (1), characterized in that the cooling device it is executed as a glove (14) by indirectly cooling at least one bleed brick (10, 11, 12) and at least partially enclosing it in the oven wall region (3), with the glove (14) being partially projecting inwardly. of the furnace lining (4) and the glove (14) in its region protruding from the furnace wall (3) is at least run by regions with a circulating cooling channel (15). Bleeding channel (1) according to claim 1, characterized in that the sleeve (14) is formed of a thermally conductive material. Bleeding channel (1) according to claim 2, characterized in that the sleeve (14) is formed of copper. Bleeding channel according to any one of claims 1, 2 or 3, characterized in that the whitening (14) is performed in one part. Bleeding channel according to any one of claims 1, 2 or 3, characterized in that the whitening (14) is made in several parts. Bleeding channel (1) according to any one of claims 1, 2, 3, 4 or 5, characterized in that the sleeve (14) is made with several circulating cooling channels (15). Bleeding channel (1) according to any one of Claims 1, 2, 3, 4, 5 or 6, characterized in that the sleeve (14) is made with connections (16, 17) for adduction and discharge. of a cooling medium. Bleeding channel (1) according to any one of claims 1, 2, 3, 4, 5, 6 or 7, characterized in that the glove (14) is made on the outside of the oven against the front area of the bleed brick (12).